Abstract
Abstract. A large part of the ice discharge from ice caps and ice sheets occurs through spatially limited flow units that may operate in a mode of steady flow or cyclic surge behaviour. Changes in the dynamics of distinct flow units play a key role in the mass balance of Austfonna, the largest ice cap on Svalbard. The recent net mass loss of Austfonna was dominated by calving from marine terminating outlet glaciers. Previous ice-surface velocity maps of the ice cap were derived by satellite radar interferometry (InSAR) and rely on data acquired in the mid-1990s with limited information concerning the temporal variability. Here, we present continuous Global Positioning System (GPS) observations along the central flowlines of two fast flowing outlet glaciers over 2008–2010. The data show prominent summer speed-ups with ice-surface velocities as high as 240% of the pre-summer mean. Acceleration follows the onset of the summer melt period, indicating enhanced basal motion due to input of surface meltwater into the subglacial drainage system. In 2008, multiple velocity peaks coincide with successive melt periods. In 2009, the major melt was of higher amplitude than in 2008. Flow velocities appear unaffected by subsequent melt periods, suggesting a transition towards a hydraulically more efficient drainage system. The observed annual mean velocities of Duvebreen and Basin-3 exceed those from the mid-1990s by factors two and four, respectively, implying increased ice discharge at the calving front. Measured summer velocities up to 2 m d−1 for Basin-3 are close to those of Kronebreen, often referred to as the fastest glacier on Svalbard.
Highlights
Limited fast-flow units are a typical feature of large ice caps and ice sheets and responsible for most of the ice flux from the interior/accumulation area towards the margin/ablation area
Ice-surface velocities gradually decreased from their summer maxima but maintaining relatively high speeds during the winter months compared to the pre-summer minimum, occurring in June
In 2008, the observed summer speed-up of both Basin-3 and Duvebreen appears closely linked to positive diurnal air temperatures/cumulative positive degree-days (PDD), a proxy for surface melt and potential input of meltwater into the englacial/subglacial drainage system
Summary
Limited fast-flow units are a typical feature of large ice caps and ice sheets and responsible for most of the ice flux from the interior/accumulation area towards the margin/ablation area. Transported towards the margin, ice is exposed to increased surface melt and, in case of marine-terminating outlets, iceberg calving. Iceberg calving allows for more rapid and abrupt ice mass loss than surface melt. Its potential contribution to eustatic sea-level rise (SLR) is suggested to account for up to 2 m by the end of this century (Pfeffer et al, 2008). This contribution is excluded from the last consensus estimate, 0.18–0.6 m SLR until 2100, by the Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment (Solomon et al, 2007)
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